Abstract: Device for expanding a fluid, which device (1) comprises an inlet (2) for a high pressure fluid, an outlet (3) for a low pressure fluid, and a control valve (4) between the aforementioned inlet (2) and outlet (3) for expanding the fluid to a predefined pressure level, characterized in that the device (1) is further provided with one or more expanders (5) for expanding the fluid, of which one or more expanders (5) are connected in parallel with the control valve (4), whereby the device (1) is provided with a controller (8) configured to control the expanders (5) based on a flow rate (Qklep) of the fluid through the control valve (4).

Abstract: Mobile oil-free multi-stage compressor device which includes at least a low-pressure stage compressor element with an inlet and an outlet and a high-pressure stage compressor element with an inlet and an outlet, wherein the outlet of low-pressure stage compressor element is connected to the inlet of the high-pressure stage compressor element through a line. The line includes an intercooler which is provided with a controllable fan. In addition, the compressor device is provided with a control unit that is configured to control a controllable fan to control the temperature at an outlet of the intercooler on the basis of the dewpoint in the line.

Abstract: A method for manufacturing an adsorption agent for treating compressed gas, which includes the steps of providing a monolithic supporting structure; producing a coating suspension that includes an adsorbent; applying the coating suspension on the supporting structure to form a coating; applying a thermal treatment to the coated supporting structure in order to sinter the coating.

Abstract: A screw compressor includes a first rotor and a second rotor, and each rotor is provided with a synchronisation gear. The screw compressor is further provided with an electric motor and one or two driving gears for driving the first rotor or second rotor. At least one of the synchronisation gears or driving gears is provided with spokes between a rim supporting a gear mesh and a corresponding gear hub.

Abstract: Compressor installation with a compressor element, an outlet with an outlet line, and a dryer, that is provided with a drying section and a regeneration section. The drying section is provided with a first inlet and a first outlet. The first inlet is connected to the outlet line. The regeneration section is provided with a second inlet and a second outlet. A regeneration line (is provided between the second inlet and a first point of the outlet line. At the second outlet a return line connects the second outlet to a second point (on the outlet line downstream of the first point. A primary portion of a heat exchanger is incorporated in the return line. A secondary portion of the heat exchanger is incorporated in an oil circuit of the compressor element.

Abstract: A computer-implemented method for assessing a condition of a pneumatic network comprising at least one compressor configured to compress a gas, and at least one pneumatic consumer, the method including the steps of detecting one or more parameters and associated context information of the gas at at least two distinct locations of the pneumatic network and at two distinct points in time; and synchronizing the detection at a first and second point in time respectively, thereby obtaining a first and second snapshot, respectively, of the pneumatic network; and assessing the condition of the pneumatic network based on the first and the second snapshot.

Abstract: A filter device separating impurities from a gas, including a filter housing having a lid and a pot; the lid having an inlet and an outlet; a filter element in the pot with a top cap and a bottom cap with a filter cartridge therebetween; the top cap has an inlet duct connected to the lid inlet so that the gas to be purified is passed through the inlet duct to the filter cartridge; a space is between the lid and the top cap which is connected to the outlet of the lid; a switching element to be installed rotatably in the lid and rotatable between an off-position in which the inlet port or the outlet port connects to respectively the inlet or outlet of the lid, and a twisted position, in which the entrance of the inlet duct of the top cap can connect to the lid inlet.

Abstract: A compressor element (1) comprising at least one compression member (2), a housing (3) and a rotatable shaft (4) rotatably connecting the at least one compression member (2) to the housing (3), wherein at least one intermediate element (5) is provided between the rotatable shaft (4) and the housing (3) for facilitating rotation of the rotatable shaft (4), wherein the compressor element (1) further comprises at least one oil injector (6) extending from an inlet port (7) to at least one nozzle (8a, 8b, 8c) via an oil channel (9), wherein the oil channel (9) is shaped to allow a substantially primary flow of oil through the channel (9) for cooling of the at least one intermediate element (5).

Abstract: An impeller includes a central shaft or a tube for mounting on a shaft; around the shaft or tube a hollow hub, which in the direction from one end to the other end increases in diameter. The hub possesses an outside and an inside oriented towards the shaft or tube; a back wall which is provided at the end of the hub with the largest diameter perpendicular to the shaft or tube which at least partially closes the hollow space of the hub; a series of blades that are attached to the outside of the hub by their base; wherein a number of flat, straight reinforcing ribs are provided which extend on the shaft or tube in an essentially radial direction and form a radial connection between the shaft or tube and the inside of the hub.

Abstract: Transmission between drive shaft and a driven shaft, which transmission includes a housing and at least a driven gearwheel that is mounted on the driven shaft and a drive gearwheel that is mounted on a drive shaft. The housing is provided with an outlet opening, which outlet opening is placed in the radial extension of one of the gearwheels.

Abstract: A minimum pressure valve (10) comprising a housing (17) with the valve inlet (11) and the valve outlet (12) connected with each other by a chamber and connecting space (22a, 22b), the minimum pressure valve (10) also comprising a valve body (21) set up in a chamber (20) moveably between a closed position in which the valve inlet (11) is closed and an open position in which the valve inlet (11) is open, the minimum pressure valve (10) also comprising components which are provided with a seal and/or sliding parts (24, 26, 30), whereby a subassembly (22) of the minimum pressure valve (10) can be disassembled and/or assembled through an opening (31) in the housing (17).

Abstract: A method is provided for detecting obstructions in a gas network with sensors, which determine the physical parameters of the gas. The gas network includes controllable throttle valves and with state sensors, which can register the status of throttle valves. The method includes: a training phase in which a mathematical model is established between the measurements of sensors in which one or a plurality of adjustable throttle valves are controlled to generate obstructions; and an operational phase in which the mathematical model established between the measurements of the first and second groups are used to detect obstructions in the gas network. The operational phase includes: calculating the reading of the first and second groups of sensors using the mathematical model; determining the difference between the calculated and read values; and determining the existence of an obstruction on the basis of the aforementioned difference.

Abstract: Method for drying compressed gas by means of a drying device with an inlet for the compressed gas to be dried and an outlet for the dried compressed gas. The drying device includes at least two vessels filled with a regenerable desiccant and an adjustable valve system including a first valve block and a second valve block that connects the inlet, respectively outlet, to the vessels. The adjustable valve system is being regulated as such that at least one vessel will dry compressed gas, while the other vessel will be regenerated and cooled successively, wherein by regulation of the valve system the vessels will each in turn dry compressed gas. The method includes calculating the time period (tads) during which a vessel (2) dries compressed gas, calculated on the basis of a (tads) formula tads=A*B.

Abstract: A method for manufacturing an adsorption agent for treating compressed gas, which includes the steps of providing a monolithic supporting structure; producing a coating suspension that includes an adsorbent; applying the coating suspension on the supporting structure to form a coating; applying a thermal treatment to the coated supporting structure in order to sinter the coating.

Abstract: A fluid-injected compressor installation (1) comprises a screw compressor (2) with a compression housing (4) in which a pair of compressor rotors (6a, 6b) are mounted. A drive motor (3) drives the compressor rotors. An inlet (7) and an outlet (8) on the screw compressor (2) supply a gas and discharge compressed gas. A gear transmission (20) between the shaft (16) of one of the compressor rotors and the motor shaft (11), includes a driven gear (18) and a driving gear (19); a motor bearing (21) on the motor shaft (11) next to the driving gear (19); and a dynamic seal (25) next to the motor bearing (21), on the drive motor (3) side, such that the motor bearing (21) is between the driving gear (19) and the seal (25).

Abstract: The present invention relates to a compressor device (1) comprising: a compressor installation (2) having at least one compressor element (3a, 3b, 3c) for compressing a suctioned gas, the compressor element (3a, 3b, 3c) being driven by an electric motor (4); a heat recuperation system (6) for recuperating heat from a compressed gas resulting from the compression of the suctioned gas, the heat recuperation system (6) comprising a piping network (7) having an inlet (8) and an outlet (9) for a coolant, said piping network (7) being provided at this inlet (8) or outlet (9) with control means with a flow rate control state variable for modifying a first flow rate of the coolant in the piping network (7); and a control unit (13) which adjusts the flow rate control state variable of the control means on the basis of a drive current of the electric motor (4) or on the basis of a second flow rate of the suctioned gas such that a temperature Tw,out at the outlet (9) of the piping network (7) is driven to a predefined

Abstract: A screw compressor element may have a housing; a cylinder bearing including an inner ring, an outer ring, a raceway, and a cylindrical rolling element that contacts the inner ring and the outer ring at a location of the raceway thereof; and a ball bearing including an inner ring, an outer ring, a raceway, and a ball shaped rolling element that contacts the inner ring and the outer ring at a location of the raceway thereof, wherein a rotor is rotatably arranged by way of the cylinder bearing and the ball bearing.

Abstract: A turbomachine includes a shaft with a first end and an impeller arranged at and coupled to the first end of the shaft, arranged together to rotate about an axis of rotation. The turbomachine further includes a friction ring clamped between an axial surface at the first end of the shaft and an opposite axial surface of the impeller.